A Mechanotransduction Apparatus To Coordinate Epithelial Collective Cell Migration.
Funder
National Health and Medical Research Council
Funding Amount
$994,596.00
Summary
Epithelial cells migrate as physically coherent collective groups, which is necessary for normal development and is disrupted as cancers progress to become invasive and spread. Collective migration requires communication so that the behaviour of individual cells is properly coordinated. In this project we investigate how the transmission of physical force between cells allows them to communicate; and test how its disruption contributes to cancer invasion.
Advancing The Spatial Analysis Of Cells In Tissues To Profile The Tumour Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$187,918.00
Summary
Tumours are composed of a mix of different cells, including cancer cells, immune cells and other cells supporting tumour growth. These cells are not organised randomly, but rather are distributed in specific patterns. Here we will develop computational methods to detect these patterns and determine what statistical tests should be used to compare samples. This project will give us the tools to investigate how the location of cells in tissues relates to treatment response and survival.
Endometrial Exosomes: A New Paradigm In Endometrial-embryo Cross-talk
Funder
National Health and Medical Research Council
Funding Amount
$726,978.00
Summary
Establishment of pregnancy requires molecular communication between the embryo and the lining of the womb (the endometrium) which enhances implantation into the womb and placental development. Nanoparticles (exosomes) released by the endometrium into the uterine cavity, carry cargo of genetic material and proteins, which may be transferred to the pre-implantation embryo. We will define functional changes induced by exosomes, that impact on implantation and the fetus’s long-term health.
The Contribution Of Host Caveolin-1 To Breast Cancer Metastasis
Funder
National Health and Medical Research Council
Funding Amount
$517,992.00
Summary
Mortality in breast cancer rises to 80% in cases where secondary tumors form in other organs. To improve outcome, a better understanding of the processes involved in cancer spread is needed. Normal cells contribute to the growth and spread of a tumour and are a target for therapy. When a protein called caveolin-1 is lost from normal cells in a tumour, the prognosis for the patient is much worse. The aim of this project is to understand how this protein can regulate the spread of breast cancer.
Regulation Of The Drosophila C-Myc Homologue In Stem Cell Growth And Division.
Funder
National Health and Medical Research Council
Funding Amount
$613,397.00
Summary
The mechanisms controlling stem cell growth and division require elucidation if we are to use stem cells in regenerative medicine and find cancer treatments. Due to experimental limitations such mechanisms are largely unknown in humans. We aim to use the vinegar fly as a model system to understand the importance of microenvironment to cancer gene control in stem cells. We will identify the secreted signals, from the neighbouring cells, required to control cancer initiation in stem cells.
The Role Of Natural Protein Inhibitors In Blocking Breast Cancer Invasion
Funder
National Health and Medical Research Council
Funding Amount
$424,139.00
Summary
The mechanisms required for breast cancer cells to spread outside of the ducts and into the surrounding breast tissue are largely unknown. There is increasing evidence that the cell layer surrounding the ducts (myoepithelium) functions to suppress invasion. We aim to test if a protein inhibitor that is expressed in these cells can preventing breast cancer invasion in models of early breast cancer and if its expression can predict those patients that are unlikely to develop invasive cancers.
Function Of The Lysophospholipid Receptor Family In Neuronal Stem Cells And Their Progenitors.
Funder
National Health and Medical Research Council
Funding Amount
$380,723.00
Summary
Stem cells have the potential to give rise to a vast array of differentiated cells. Neuronal stem cells (NSC) can differentiate into progenitor cells which can themselves differentiate into cells of the nervous system: neurons and macroglial cells (astrocytes, oligodendrocytes, Schwann cells). This in turn can assist in the treatment of degenerative diseases such as multiple sclerosis, Parkinson's disease, motoneuron desease etc. Our project aims to study the effects on NSC and their progenitor ....Stem cells have the potential to give rise to a vast array of differentiated cells. Neuronal stem cells (NSC) can differentiate into progenitor cells which can themselves differentiate into cells of the nervous system: neurons and macroglial cells (astrocytes, oligodendrocytes, Schwann cells). This in turn can assist in the treatment of degenerative diseases such as multiple sclerosis, Parkinson's disease, motoneuron desease etc. Our project aims to study the effects on NSC and their progenitor cells of the lysophospholipids lysophosphatidic acid (LPA) and sphingosine-1-phosphate (S1P), bioactive molecules known to play an essential role in the nervous system during development and inflammation. Our project aims to understand the mechanisms of action of these molecules in NSC maintenance, proliferation, differentiation and migration. By understanding how these molecules are able to regulate NSC biology will provide new avenues in the development of tools necessary for stem cell therapy.Read moreRead less
A Novel Mechanism For The Regulation Of T Cell Shape And Function.
Funder
National Health and Medical Research Council
Funding Amount
$384,398.00
Summary
T cells are a key component of the immune system, and an understanding of their regulation has already lead to important therapeutic interventions. It is now apparent that the shape of the T cell impacts upon its ability to be activated, to migrate through the body, and to kill target cells. We have identified a novel means by which T cell shape is controlled, involving a group of proteins which orchestrate molecular traffic throughout the cell. This project application is to elucidate the mecha ....T cells are a key component of the immune system, and an understanding of their regulation has already lead to important therapeutic interventions. It is now apparent that the shape of the T cell impacts upon its ability to be activated, to migrate through the body, and to kill target cells. We have identified a novel means by which T cell shape is controlled, involving a group of proteins which orchestrate molecular traffic throughout the cell. This project application is to elucidate the mechanisms by which the group of proteins regulates T cell shape and function. We will test whether the proteins act together to integrate signals throughout the entire T cell, and will test whether the proteins influence T cell function in the test tube and in the mouse.Read moreRead less